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Thermodynamics-Kinetics-Balanced Metal-Organic Framework for In-Depth Radon Removal under Ambient Conditions.

Xia WangFuyin MaShengtang LiuLixi ChenShunshun XiongXing DaiBo TaiLinwei HeMengjia YuanPinhong MiShicheng GongGuodong LiYi TaoJun WanLong ChenXuhui SunQuan TangLinfeng HeZaixing YangZhifang ChaiShu-Ao Wang
Published in: Journal of the American Chemical Society (2022)
Radon (Rn), a ubiquitous radioactive noble gas, is the main source of natural radiation to human and one of the major culprits for lung cancer. Reducing ambient Rn concentration by porous materials is considered as the most feasible and energy-saving option to lower this risk, but the in-depth Rn removal under ambient conditions remains an unresolved challenge, mainly due to the weak van der Waals (vdW) interaction between inert Rn and adsorbents and the extremely low partial pressure (<1.8 × 10 -14 bar, <10 6 Bq/m 3 ) of Rn in air. Adsorbents having either favorable adsorption thermodynamics or feasible diffusion kinetics perform poorly in in-depth Rn removal. Herein, we report the discovery of a metal-organic framework (ZIF-7-Im) for efficient Rn capture guided by computational screening and modeling. The size-matched pores in ZIF-7-Im abide by the thermodynamically favorable principle and the exquisitely engineered quasi-open apertures allow for feasible kinetics with little sacrifice of sorption thermodynamics. The as-prepared material can reduce the Rn concentration from hazardous levels to that below the detection limit of the Rn detector under ambient conditions, with an improvement of at least two orders of amplitude on the removal depth compared to the currently best-performing and only commercialized material activated charcoal.
Keyphrases
  • metal organic framework
  • air pollution
  • particulate matter
  • optical coherence tomography
  • endothelial cells
  • magnetic resonance
  • heavy metals
  • induced pluripotent stem cells
  • sensitive detection